Tuning the Crystallization Mechanism by Composition Vacancy in Phase Change Materials

Wen Xiong Song; Qiongyan Tang; Jin Zhao; Muriel Veron; Xilin Zhou; Yonghui Zheng; Daolin Cai; Yan Cheng; Tianjiao Xin; Zhi Pan Liu; Zhitang Song

doi:10.1021/acsami.3c18538

Tuning the Crystallization Mechanism by Composition Vacancy in Phase Change Materials

Wen Xiong Song, Qiongyan Tang, Jin Zhao, Muriel Veron, Xilin Zhou, Yonghui Zheng, Daolin Cai, Yan Cheng, Tianjiao Xin, Zhi Pan Liu, Zhitang Song

School of Physics and Electronic Science

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Interface-influenced crystallization is crucial to understanding the nucleation- and growth-dominated crystallization mechanisms in phase-change materials (PCMs), but little is known. Here, we find that composition vacancy can reduce the interface energy by decreasing the coordinate number (CN) at the interface. Compared to growth-dominated GeTe, nucleation-dominated Ge₂Sb₂Te₅ (GST) exhibits composition vacancies in the (111) interface to saturate or stabilize the Te-terminated plane. Together, the experimental and computational results provide evidence that GST prefers (111) with reduced CN. Furthermore, the (8 - n) bonding rule, rather than CN6, in the nuclei of both GeTe and GST results in lower interface energy, allowing crystallization to be observed at the simulation time in general PCMs. In comparison to GeTe, the reduced CN in the GST nuclei further decreases the interface energy, promoting faster nucleation. Our findings provide an approach to designing ultrafast phase-change memory through vacancy-stabilized interfaces.

Original language	English
Pages (from-to)	15023-15031
Number of pages	9
Journal	ACS Applied Materials and Interfaces
Volume	16
Issue number	12
DOIs	https://doi.org/10.1021/acsami.3c18538
State	Published - 27 Mar 2024

Keywords

Te-terminated boundary
crystallization mechanism
interface-influenced crystallization
interface-influenced grain size
phase change material
vacancy-stabilized interface

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10.1021/acsami.3c18538

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title = "Tuning the Crystallization Mechanism by Composition Vacancy in Phase Change Materials",

abstract = "Interface-influenced crystallization is crucial to understanding the nucleation- and growth-dominated crystallization mechanisms in phase-change materials (PCMs), but little is known. Here, we find that composition vacancy can reduce the interface energy by decreasing the coordinate number (CN) at the interface. Compared to growth-dominated GeTe, nucleation-dominated Ge2Sb2Te5 (GST) exhibits composition vacancies in the (111) interface to saturate or stabilize the Te-terminated plane. Together, the experimental and computational results provide evidence that GST prefers (111) with reduced CN. Furthermore, the (8 - n) bonding rule, rather than CN6, in the nuclei of both GeTe and GST results in lower interface energy, allowing crystallization to be observed at the simulation time in general PCMs. In comparison to GeTe, the reduced CN in the GST nuclei further decreases the interface energy, promoting faster nucleation. Our findings provide an approach to designing ultrafast phase-change memory through vacancy-stabilized interfaces.",

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author = "Song, \{Wen Xiong\} and Qiongyan Tang and Jin Zhao and Muriel Veron and Xilin Zhou and Yonghui Zheng and Daolin Cai and Yan Cheng and Tianjiao Xin and Liu, \{Zhi Pan\} and Zhitang Song",

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doi = "10.1021/acsami.3c18538",

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T1 - Tuning the Crystallization Mechanism by Composition Vacancy in Phase Change Materials

AU - Song, Wen Xiong

AU - Tang, Qiongyan

AU - Zhao, Jin

AU - Veron, Muriel

AU - Zhou, Xilin

AU - Zheng, Yonghui

AU - Cai, Daolin

AU - Cheng, Yan

AU - Xin, Tianjiao

AU - Liu, Zhi Pan

AU - Song, Zhitang

PY - 2024/3/27

Y1 - 2024/3/27

N2 - Interface-influenced crystallization is crucial to understanding the nucleation- and growth-dominated crystallization mechanisms in phase-change materials (PCMs), but little is known. Here, we find that composition vacancy can reduce the interface energy by decreasing the coordinate number (CN) at the interface. Compared to growth-dominated GeTe, nucleation-dominated Ge2Sb2Te5 (GST) exhibits composition vacancies in the (111) interface to saturate or stabilize the Te-terminated plane. Together, the experimental and computational results provide evidence that GST prefers (111) with reduced CN. Furthermore, the (8 - n) bonding rule, rather than CN6, in the nuclei of both GeTe and GST results in lower interface energy, allowing crystallization to be observed at the simulation time in general PCMs. In comparison to GeTe, the reduced CN in the GST nuclei further decreases the interface energy, promoting faster nucleation. Our findings provide an approach to designing ultrafast phase-change memory through vacancy-stabilized interfaces.

AB - Interface-influenced crystallization is crucial to understanding the nucleation- and growth-dominated crystallization mechanisms in phase-change materials (PCMs), but little is known. Here, we find that composition vacancy can reduce the interface energy by decreasing the coordinate number (CN) at the interface. Compared to growth-dominated GeTe, nucleation-dominated Ge2Sb2Te5 (GST) exhibits composition vacancies in the (111) interface to saturate or stabilize the Te-terminated plane. Together, the experimental and computational results provide evidence that GST prefers (111) with reduced CN. Furthermore, the (8 - n) bonding rule, rather than CN6, in the nuclei of both GeTe and GST results in lower interface energy, allowing crystallization to be observed at the simulation time in general PCMs. In comparison to GeTe, the reduced CN in the GST nuclei further decreases the interface energy, promoting faster nucleation. Our findings provide an approach to designing ultrafast phase-change memory through vacancy-stabilized interfaces.

KW - Te-terminated boundary

KW - crystallization mechanism

KW - interface-influenced crystallization

KW - interface-influenced grain size

KW - phase change material

KW - vacancy-stabilized interface

UR - https://www.scopus.com/pages/publications/85188142890

U2 - 10.1021/acsami.3c18538

DO - 10.1021/acsami.3c18538

M3 - 文章

C2 - 38498850

AN - SCOPUS:85188142890

SN - 1944-8244

VL - 16

SP - 15023

EP - 15031

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 12

ER -

Tuning the Crystallization Mechanism by Composition Vacancy in Phase Change Materials

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